EP0610584A1 - Fuel injection de vice with pilot- and main-injection of different fuels through a one-needle injection valve - Google Patents

Abstract

The invention relates to a fuel injection device for pilot and main injection of different fuels. For this purpose a single-needle injection valve (9) of comparatively simple design, a specially functioning injection pump (1) and external means of control (19, 38, 40) are provided, by means of which, on completion of one injection, refilling of pilot injection fuel and main injection fuel can be performed with the aim of fuel stratification in the injection valve (9). <IMAGE>

Description

The invention relates to a fuel injection device for a pre- and main injection of different fuels via a single-needle injection valve, wherein pre-injection fuel is introduced from a low-pressure feed device into the injection valve, there through the spring chamber receiving the valve needle in the closing direction and through a channel into the The valve needle is fed into the interior of the valve needle and upstream from there via throttle bores near the seat thereof, and main injection fuel is then introduced from an injection pump via an injection line or directly and a valve-internal channel into the nozzle antechamber behind the upstream pre-injection fuel.

The invention is based on a fuel injection device known from EP 0064146 B1 for a pre-injection and main injection of different fuels, a single-needle injection valve being used and the fuels being supplied as stated above. However, the single-needle injection valve used here has a relatively complicated and therefore expensive structure. This complexity results from the design of the valve-internal supply paths for the pre-injection fuel and a relief valve built into the supply path for the main injection fuel. The valve needle is hollow and open to the rear. Dipped into this cavity is a bolt that connects to the pressure plate of the closing pressure spring, which extends from the front to close to the tip of the nozzle needle, has a longitudinal flattening on the outside, a transverse bore and a longitudinal bore for the passage of pre-injection fuel, and also a seat for the ball of a check valve forms. The latter also has a compression spring acting on the ball, serves to prevent a backflow of fuel during the injection and is installed in the cavity of the valve needle in front of said bolt. Throttle bores branch off from the area of the relevant receiving space, which enable the pre-injection fuel to be discharged into the nozzle antechamber. The relief valve built into the supply channel for main injection fuel is also relatively complicated, it consists of a compression spring and a special relief piston, which is realized by a stepped piston, which has a blind hole at the beginning and transverse holes extending from it, as well as a shoulder, for which a corresponding seat is formed inside the valve.

Although this known solution allows an exact metering of the amount of pre-storage fuel, it has to accept other disadvantages in addition to the disadvantages already mentioned, which are discussed below. The amount of storage fuel is structurally determined on the basis of the injection valve design and therefore cannot be varied. In addition, the installation of the relief valve on the nozzle side entails additional pressure losses and damage volumes. Furthermore, the pressure in the injection line after completion of an injection must be lower than the opening pressure of the nozzle-side relief valve. This means either a high opening pressure for this, which is difficult to represent due to space constraints, combined with a high pressure loss, or a pressure relief valve overloading on the injection pump side with the disadvantages known from such injectors such as cavitation, scattering of the injection quantity and start and the like.

It is therefore an object of the invention to improve a fuel injector of the type mentioned in such a way that simpler and therefore cheaper single-needle injectors can be used, and in addition, variable, quantitative but precisely adjusted metering of the pilot and main injection fuel is possible in all load ranges of the internal combustion engine problematic conditions can be avoided after the end of an injection process.

• daß die Ventilnadel hohl ausgebildet und dieser rückseitig verschlossene Hohlraum über eine Füllbohrung von außen her mit Voreinspritzkraftstoff füllbar ist, über einen Zuführkanal, in den ein nur in Speiserichtung durchlässiges Rückschlagventil eingebaut ist,
• daß zur zeit- und mengenmäßig exakten Zumessung des Voreinspritzkraftstoffes in der externen Zuleitung ein steuerbares Magnetventil eingebaut ist,
• daß der ventilinterne Haupteinspritzkraftstoff-Zuführkanal nur durch miteinander kommunizierende Bohrungsabschnitte ohne Einbauten gebildet ist,
• daß sich an jeden Pumpenraum der Einspritzpumpe ein ein Druckventil und eine Druckfeder aufnehmender Pumpenausgangsraum und daran entweder über die Einspritzleitung oder direkt der einspritzventilinterne Zuführkanal anschließt, und
• daß die Einspritzpumpe nur zur Druckerzeugung und zum Vorschub der dem Druckventil in den anschließenden Leitungswegen nachgelagerten Kraftstoffsäule dient, wobei jedes Druckventil beim Pumpenkolben-Hub als Druckkolben wirkt und gleichzeitig eine seitlich in den Pumpenausgangsraum einmündende Füllbohrung absperrt, über die nach Beendigung jedes Einspritzvorganges und Rückführung des Druckventils in Schließstellung der dadurch entstehende, der eingespritzten Kraftstoffmenge entsprechende Hohlraum in besagten Leitungswegen von einer Niederdruck-Speiseeinrichtung her wieder mit Haupteinspritzkraftstoff auffüllbar ist, und zwar gesteuert kurz vor oder nach Beendigung der Voreinspritzkraftstoff-Nachfüllung über ein in die Zuleitung eingebautes Magnetventil.

According to the invention, this object is achieved by

• that the valve needle is hollow and this cavity, which is closed on the rear side, can be filled from the outside with pre-injection fuel via a filling hole, via a feed channel into which a check valve which is only permeable in the feed direction is installed,
• that a controllable solenoid valve is installed in the external supply line for exact metering of the pre-injection fuel,
• that the valve-internal main injection fuel supply channel is formed only by bore sections communicating with one another without internals,
• that each pump chamber of the injection pump has a pressure valve and a compression spring receiving pump outlet chamber and is connected either via the injection line or directly to the injection valve internal feed channel, and
• that the injection pump is only used to generate pressure and to advance the fuel column downstream of the pressure valve in the subsequent line paths, each pressure valve acting as a pressure piston during the pump piston stroke and at the same time shutting off a filling hole which opens laterally into the pump outlet space and via which after the end of each injection process and return of the Pressure valve in the closed position of the resulting cavity corresponding to the amount of fuel injected in said conduit paths from a low-pressure feed device can be refilled with main injection fuel, controlled shortly before or after completion of the pre-injection fuel refill via a solenoid valve built into the supply line.

By laying the control members responsible for the exact metering of the pre-injection fuel according to the invention and those control members that are responsible for the exact replenishment of the cavity in the main injection fuel line paths given after the end of an injection process, both the injection valves and the injection pump can also be designed to be comparatively simple. The additional structural effort for the external control means is in any case less expensive than a more complicated design of the injection valves and the injection pump. In addition, these external control means, namely the two solenoid valves in conjunction with the control device controlling their operation, enable the pre-injection fuel to be precisely pre-stored in terms of time and quantity in all operating areas of the internal combustion engines and to replenish the cavity with main injection fuel resulting from the closing of an injection pump-side pressure valve in the subsequent line paths , so that at the beginning of a pump piston-side delivery stroke in the injection valve, a clearly defined stratification of the pre-injection fuel and the main injection fuel is given and, moreover, the line path previously given by the pressure line and the pump outlet space is completely filled with the main injection fuel. For a pump stroke on the pump piston side, fuel is injected with exactly the amount of fuel that is displaced by the stroke of the pressure valve from the subsequent line paths. Cavitation damage, a spread of the injection quantity and start and an injection pressure that is too low, such as can occur in a disadvantageous form in the known fuel injection device discussed at the outset, do not occur with the fuel injection device according to the invention due to its design.

Advantageous refinements and developments of the fuel injection device according to the invention are characterized in the subclaims.

The fuel injection device according to the invention is explained in more detail below on the basis of an exemplary embodiment shown in the drawing.

The fuel injection device has an injection pump 1 with pump pistons 2 controlled by cams (not shown), each of which has conventional control grooves 3, 4 and oblique control edges 5 and can be rotated by a control device (also not shown) for power control. The pump chambers 7, each of which can be filled with fluid such as oil or diesel fuel from a supply device via a laterally opening control bore 6, are adjoined in each case by a pump outlet chamber 8 and an injection line 11 connected to an internally provided with a single-needle injection valve 9. If the single-needle injection valve 9 is combined with the injection pump 1 to form a pump nozzle element, the injection line 11 is omitted. The connection bore 12 between each pump chamber 7 and pump outlet chamber 8 is provided on the rear with a conical extension 13, which serves as a seat for a in the pump outlet chamber 8 low-pressure valve 14 is used, which is acted upon in the closing direction by a pressure spring 15 also installed in the pump outlet chamber 8. In contrast to conventional injection pumps, in which the delivered fuel is fed directly to an injection valve through the pump piston stroke, the injection pump according to the invention only serves to build up pressure and to advance the amount of main injection fuel coming in for injection, which is successively supplied to the line paths 8, 11, 10 adjoining the pressure valve 14. Each pressure valve 14 acts as a pressure piston during the pump piston stroke, which pushes the fuel column behind it by its stroke movement and at the same time shuts off a filling bore 16 opening laterally into the pump outlet space 8, via which, after the completion of each injection process and return of the pressure valve 14 to its closed position, thereby resulting cavity corresponding to the amount of fuel injected in said conduits 8, 11, 10 can be refilled with main injection fuel from a low-pressure feed device 17, controlled shortly before or after completion of a pre-injection fuel refill via a solenoid valve 19 built into the external feed line 18 .

Each single-needle injection valve 9 assigned to a cylinder of the internal combustion engine has a hollow valve needle 20, the cavity 21 of which is closed on the rear side can be filled with pre-injection fuel from the outside via a filling bore 22, specifically via an internal valve consisting of parts 23/1, 23 / 2, 23/3, 23/4, 23/5, 23/6 composing feed channel 23, in which a check valve 24 which is only permeable in the feed direction is installed. The latter serves to prevent a backflow of pre-injection fuel during the injection. The cavity 21 is connected via holes 25 located near the valve needle tip 27 to the nozzle antechamber 26 which extends around the front part of the valve needle 20 and widens at the rear.

To form the cavity 21, the valve needle 20 is preferably drilled from its rear coaxially to almost its tip 27. This cavity 21 designed in this way is preferably closed on the rear by a partially immersed spacer bolt 28, which establishes the connection between the valve needle 20 and a pressure plate 29, on which a compression spring 30 acting on the valve needle 20 in the closing direction is supported at the front. This compression spring 30 presses the valve needle 20 in the closed position against a conical valve seat 31, in front of which nozzle bores 32 open into the combustion chamber. At the valve needle 20 there is an annular lifting surface 33, approximately through the middle of its longitudinal extension at the transition between its smaller diameter front and larger diameter rear section, through which the valve needle with correspondingly acting in the nozzle vestibule 26 fuel pressure can be raised in the open position.

The filling bore 22 is preferably provided behind the annular lifting surface 33 of the valve needle 20 in the rear half thereof and is designed as a transverse bore which extends from an annular groove 34 provided on the outside of the valve needle 20, which communicates with the supply channel 23 in each valve needle position. The latter in turn preferably includes the spring chamber receiving the compression spring 30 (section 23/2), an annular gap (section 23/3) around the pressure plate 29 and the spacer bolt 28, and then sits down with a transverse channel (section 23/4), one Vertical bore (section 23/5), in which the check valve 24 is installed, and continues with an oblique bore (section 23/6), the latter opening laterally at the level of the filling bore 22 into the receiving bore 35 guiding the valve needle 20. Basically, the aim should be that the check valve 24 is installed in the valve-internal feed channel 23 as close as possible before the junction point in the receiving bore 35.

The valve-internal feed channel 23 can be supplied with pre-injection fuel from a low-pressure feed device 36 via a feed line 37, in which a cyclically controllable solenoid valve 38 is built in for the exact metering in terms of time and quantity.

The main injection fuel supply channel 10 opening into the nozzle antechamber 26 is formed internally in the valve only by bore sections communicating with one another without any internals.

The two solenoid valves 19, 38 are preferably combined in a common valve block 39 which is installed in the two supply lines 18, 37 running over it. The two solenoid valves 19, 38 can be controlled by an electronic control device 40, which operates on the basis of their supplied angle of rotation signals φ of the crankshaft of the internal combustion engine or a camshaft controlling the gas exchange valves thereof or the pump pistons 2 of the injection pump 1 and in which the opening and closing times of the two solenoid valves 19, 38 are stored as values dependent on the angle of rotation.

Each of the two fuels is provided in its own storage tank 41, 42 and is made from it by the associated low-pressure feed device 17 or 36 eligible. Each of the latter consists of a feed pump 17/1 or 36/1 and a pressure relief valve 17/2 or 36/2, which limits their delivery pressure to approximately 2 to 4 bar. For example, diesel fuel can be used as the ignitable pilot injection fuel and a diesel water emulsion or ethanol can be used as the ignition carrier main injection fuel. In the event that diesel fuel is used as the ignitable fuel, the pump chambers 7 of the injection pump can also be supplied with the appropriate fuel from the corresponding low-pressure feed device 36.

The function of the fuel injection according to the invention is described below on the basis of a complete fuel stratification process and subsequent injection process.

After the end of an injection, the cavities given in the injection system are first refilled. The two fuels are basically stratified in such a way that pre-injection fuel is present in the vicinity of the nozzle bores 32 in the nozzle vestibule 26 and the main injection fuel is stratified behind it, that is to say at a greater distance. After an injection has ended, the line paths 8, 11 adjoining the pressure valve 14 and all the channels inside the valve are depressurized. This state occurs when the pressure in the pump chamber 7 collapses at the end of the pump piston stroke and, as a result, the valve needle 20 closes and the pressure valve 14 returns to its closed position. Subsequently, the solenoid valve 38 is first opened from the control device 40, so that pre-injection fuel can be introduced into the injection valve 36 through the low-pressure feed device 36, specifically via the feed channel 23 with its parts 23/1, 23/2, 23/3, 23 / 4, 23/5, 23/6, as a result of which the fuel located in the cavity 21 of the valve needle 20 is discharged into the nozzle antechamber 26 via the throttle bores 25 - while displacing the main injection fuel still located in the nozzle antechamber 26 back into the supply channel 10. As soon as the corresponding amount of pre-injection fuel is stored upstream in the nozzle antechamber 26, the solenoid valve 38 is closed again by the control device 40 and the pre-injection fuel pre-storage is thus ended. Subsequently or with a slight advance in time before the closing of the magnetic valve 38, the solenoid valve 19 is opened, so that then main injection fuel from the low-pressure feed device 17 via the feed line 18 and the filling bore 16 for filling of the cavity given in the conduction paths 8, 11 and 10 can be conveyed. As a result, the main injection fuel in the valve-internal supply channel 10 is subsequently added to the pre-injection fuel which is already upstream of the latter. As soon as this refilling process has ended, the solenoid valve 18 is closed again by the control device 40. The opening time for the solenoid valve 18 is so large that all cavities can always be filled. The sequence described also leads to an exact metering if the set amount was smaller than the desired pre-injection fuel amount. Said refilling processes take place practically during the downward stroke of the associated pump piston 2. In the subsequent pump piston upward stroke, which is decisive for the injection, the pump piston 2 displaces the working medium from the pump chamber 7 after the control bore 6 has been closed. As a result, the pressure valve 14 acting as a pressure piston is raised against the resistance of the compression spring 15, the filling bore 16 being closed. As a result, a pressure wave is generated via the main injection fuel column in the pump outlet space 8, the subsequent injection line 11 and the valve-internal feed channel 10, by means of which the valve needle 20 is raised and an injection takes place, the pre-injection fuel first and then the main injection fuel via the nozzle bores 32 in the combustion chamber of the internal combustion engine are injected. As soon as the control bore 6 is opened by the pump piston 2, the pressure wave transmitted via the fuel column breaks down. As a result, the valve needle 20 and the pressure valve 14 close, which again results in a cavity in the size of the injected fuel quantity in the line paths 8, 11, 10 behind it. In the subsequent downward gear of the pump piston 2, the injection system is again refilled with pre-injection fuel and main injection fuel in the manner indicated above.

Claims (13)

Fuel injection device for a pre-injection and main injection of different fuels via a single-needle injection valve, whereby pre-injection fuel is introduced into the injection valve from a low-pressure feed device, there it is fed through the spring chamber which acts on the valve needle in the closing direction and is fed into the interior of the valve needle via a channel and from there via throttle bores in the nozzle antechamber given near their seat, and wherein main injection fuel is subsequently introduced from an injection pump via an injection line or directly and a valve-internal channel into the nozzle antechamber behind the upstream pre-injection fuel,
characterized, - That the valve needle (20) is hollow and this cavity, which is closed on the rear side, can be filled from the outside with pre-injection fuel via a filling bore (22), via a feed channel (23) into which a check valve (24) which is only permeable in the feed direction is installed, - An appropriately controllable solenoid valve (38) is installed in the external feed line (37) for the exact metering of the pre-injection fuel in terms of time and quantity, - That the valve-internal main injection fuel supply channel (10) is formed only by mutually communicating bore sections without internals, - That each pump chamber (7) of the injection pump (1) has a pressure valve (14) and a compression spring (15) receiving the pump outlet chamber (8) and is connected either via the injection line (11) or directly to the injection valve internal feed channel (10), and - That the injection pump (1) is only used to generate pressure and to feed the pressure valve (14) in the subsequent line paths (8, 11, 10) downstream fuel column, each pressure valve (14) at Pump piston stroke acts as a pressure piston and at the same time shuts off a filling bore (16) opening into the side of the pump outlet space (8), via which, after each injection process and return of the pressure valve (14) in the closed position, the resulting cavity corresponding to the amount of fuel injected in said conduit paths (8, 11, 10) from a low-pressure feed device (17) can be refilled with main injection fuel, controlled shortly before or after completion of the pre-injection fuel refill via a solenoid valve (19) built into the feed line (18). Fuel injection device according to claim 1, characterized in that the valve needle (20) for forming the cavity (21) is drilled coaxially from its rear side up to close to its tip (25). Fuel injection device according to one of the preceding claims, characterized in that the cavity (21) of the valve needle (20) is closed on the rear by a partially immersed spacer bolt (28) connected to the pressure plate (29) of the compression spring (30). Fuel injection device according to one of the preceding claims, characterized in that the filling bore (22) behind the annular lifting surface (33) of the valve needle (20) is provided in the rear half thereof. Fuel injection device according to Claim 4, characterized in that the filling bore (22) is designed as a transverse bore which extends from an annular groove (34) which is provided on the outside of the valve needle (20) and which communicates with the feed channel (23) in each valve needle position. Fuel injection device according to claim 1, characterized in that the check valve (24) is installed in the valve-internal feed channel (23) as close as possible before it opens into the receiving bore (35) guiding the valve needle (20). Fuel injection device according to claims 1, 3 and 6, characterized in that the feed channel (23) the spring chamber (23/2) receiving the compression spring (30), an annular gap (23/3) around the pressure plate (29) and encloses the spacer bolt (28) and then continues with a transverse channel (23/4), a vertical bore (23/5) into which the check valve (24) is installed, and an oblique bore (23/6) that continues in height the filling bore (22) opens laterally into the receiving bore (35) guiding the valve needle (20). Fuel injection device according to Claim 1, characterized in that the two solenoid valves (19, 38) can be controlled by an electronic control device (40) which, on the basis of their supplied angle of rotation signals (φ) from the crankshaft or one of the gas exchange valves or the pump pistons (2) the camshaft controlling the injection pump (1) and in which the opening and closing times of the two solenoid valves (19, 38) are stored as values dependent on the angle of rotation. Fuel injection device according to Claim 8, characterized in that the two solenoid valves (19, 38) are combined in a common valve block (39) through which the two supply lines (18, 37) run. Fuel injection device according to Claim 1, characterized in that each of the two fuels is provided in its own storage tank (41, 42) and can be conveyed from it by the associated low-pressure feed device (17, 36). Fuel injection device according to Claim 1, characterized in that each of the two low-pressure feed devices (17, 36) consists of a feed pump (17/1, 36/1) and a pressure relief valve (17/2, which limits the feed pressure to approximately 2 to 4 bar). 36/2) exists. Fuel injection device according to Claim 1, characterized in that the pump chambers (7) of the injection pump (1) can also be supplied with the appropriate fuel from the low-pressure feed device (36) which delivers the ignitable fuel. Fuel injection device according to claim 1, characterized by its use for the pre-injection of diesel fuel and for the main injection of a diesel-water emulsion or ethanol.

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